U.S. patent number 6,698,046 [Application Number 10/106,637] was granted by the patent office on 2004-03-02 for air mattress control unit.
This patent grant is currently assigned to Sunflower Medical, L.L.C.. Invention is credited to Shang-Neng Wu.
United States Patent |
6,698,046 |
Wu |
March 2, 2004 |
Air mattress control unit
Abstract
The system of the present invention is a system for supplying
air and controlling the flow of air into and out of the chambers of
a patient supporting air mattress. It includes an electric motor
powered variable speed blower, a two position rotary valve, air
mattress supply lines communicating between the rotary valve and
the chambers of the air mattress, a continuous exhaust line also
connected to the rotary valve, stepper motor controlled valves in
the air mattress supply lines, pressure sensors between the stepper
motor controlled valves and the chambers of the air mattress and a
control unit for controlling the stepper motor controlled valves to
control the amount by which the chambers of the air mattress are
inflated.
Inventors: |
Wu; Shang-Neng (Taipei,
TW) |
Assignee: |
Sunflower Medical, L.L.C.
(Ellis, KS)
|
Family
ID: |
31721364 |
Appl.
No.: |
10/106,637 |
Filed: |
March 26, 2002 |
Current U.S.
Class: |
5/713;
137/625.15; 137/625.21; 5/714 |
Current CPC
Class: |
A47C
27/082 (20130101); A47C 27/083 (20130101); A47C
27/10 (20130101); A61G 7/05776 (20130101); F16K
11/072 (20130101); A61G 2203/34 (20130101); Y10T
137/86638 (20150401); Y10T 137/86533 (20150401) |
Current International
Class: |
A47C
27/08 (20060101); A47C 27/10 (20060101); A61G
7/057 (20060101); F16K 11/072 (20060101); F16K
11/06 (20060101); A47C 027/10 (); F16K
003/26 () |
Field of
Search: |
;5/713,710,706,714,914
;137/625.13,625.15,625.21 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Santos; Robert G.
Attorney, Agent or Firm: Chase Law Firm, L.C.
Parent Case Text
CROSS REFERENCES TO RELATED APPLICATIONS
This application claims the benefit of U.S. Provisional Patent
Application No. 60/278,925 filed Mar. 26, 2001 and U.S. Provisional
Patent Application No. 60/292,090 filed May 17, 2001.
Claims
I claim:
1. A system for controlling the flow of air from between an outside
environment, a blower having an intake port and an exhaust port and
the chambers of a patient supporting low air loss air mattress,
comprising; a rotary valve having a housing and a gate member, the
housing including an inlet port communicating with the blower
exhaust port, air mattress supply ports communicating with lines
supplying the chambers of the air mattress and an outlet port
communicating with the blower intake port, the housing rotatably
receiving the gate member, the gate member divided by a wall into a
first portion and a second portion and further having a first port
communicating the first portion with the outside environment, a
second port communicating with the first portion and a third port
communicating with the second portion, the gate member rotatable
between a first position aligning the gate member second port with
the valve housing outlet port and communicating the gate member
second portion with the valve housing inlet port and the air
mattress supply ports, thereby communicating the blower intake with
the outside environment and communicating the blower exhaust with
the air mattress supply ports, and a second position aligning the
gate member third port with the valve housing outlet port and
communicating the first portion of the gate member with the valve
housing inlet port and communicating the second portion of the gate
member with the air mattress supply ports, thereby communicating
the blower exhaust with the outside environment and communicating
the blower intake with the air mattress supply ports to quickly
deflate the air mattress.
2. The system of claim 1, wherein the air mattress supply lines
have electrically controlled valves for controlling the amount of
air that can flow therethrough.
3. The system of claim 1, wherein the air mattress supply lines
have electrically controlled valves for controlling the amount of
air that can flow therethrough, and, the air mattress supply lines
have pressure sensors interposed between the valves and the
chambers of the air mattress for sensing the back pressure in the
chambers of the air mattress, and wherein, a control unit
operatively connected to the pressure sensors and the electrically
controlled valves receives signals from the pressure sensors and
responds to those signals by opening or closing the valves until
the pressure sensors indicate a predetermined pressure.
4. The system of claim 1, wherein the air mattress supply lines
have electrically controlled valves for controlling the amount of
air that can flow therethrough, the air mattress supply lines have
pressure sensors interposed between the valves and the chambers of
the air mattress for sensing the back pressure in the chambers of
the air mattress, and, a control unit is operatively connected to
the pressure sensors and the valves, the programmable control unit
receiving pressure signals from the pressure sensors and responding
to those pressure signals by (1) determining if the pressure signal
indicates if a pressure is within a selected range of pressures or
above or below a selected range of pressures, (2) transmitting a
signal to incrementally close the valve in a line having a pressure
that is above the selected range of pressures, (3) transmitting a
signal to incrementally open the valve in a line having a pressure
that is below the selected range of pressures.
5. The system of claim 1, wherein the air mattress supply lines
have stepper motor controlled valves for controlling the amount of
air that can flow therethrough, the air mattress supply lines have
pressure sensors interposed between the valves and the chambers of
the air mattress for sensing the back pressure in the chambers of
the air mattress, and, a control unit is operatively connected to
the blower motor, the pressure sensors and the valves, the control
unit receiving pressure signals from the pressure sensors and
responding to those pressure signals by (1) determining if the
pressure signal indicates if a pressure is within a selected range
of pressures or above or below a selected range of pressures, (2)
transmitting a signal to incrementally close the valve in a line
having a pressure that is above the selected range of pressures,
(3) transmitting a signal to incrementally open the valve in a line
having a pressure that is below the selected range of pressures,
(4) transmitting a signal to incrementally increase the supply of
electrical power to the blower motor to increase the blower output
if a pressure in a line is below a selected range of pressures and
the valve in that line is completely open.
6. The system of claim 1, wherein the air mattress supply lines
have stepper motor controlled valves for controlling the amount of
air that can flow therethrough, the air mattress supply lines have
pressure sensors interposed between the valves and the chambers of
the air mattress for sensing the back pressure in the chambers of
the air mattress, a control unit is operatively connected to the
blower motor, the pressure sensors and the valves, the control unit
receiving pressure signals from the pressure sensors and responding
to those pressure signals by (1) determining if the pressure signal
indicates if a pressure is within a selected range of pressures or
above or below a selected range of pressures, (2) transmitting a
signal to incrementally close the valve in a line having a pressure
that is above the selected range of pressures, (3) transmitting a
signal to incrementally open the valve in a line having a pressure
that is below the selected range of pressures, (4) transmitting a
signal to incrementally increase the supply of electrical power to
the blower motor to increase the blower output if a pressure in a
line is below a selected range of pressures and the valve in that
line is completely open, and the control unit is able to receive
inputs for the height and weight of the patient, the control unit
also having an algorithm for determining acceptable air mattress
supply line back pressures corresponding to patient and mattress
interface pressures given input values for patient weight and
height, whereby the valves may be controlled to maintain patient
and mattress interface pressures that are below pre-determined
values.
7. A system for controlling the flow of air from between an outside
environment, a blower having an intake port and an exhaust port and
the chambers of a patient supporting low air loss air mattress,
comprising; a rotary valve having a cylindrical housing and a gate
member, the housing including a base wall and a cylindrical outer
wall, an inlet port in the outer wall that communicates with the
blower exhaust port, a pattern of air mattress supply ports in the
outer wall communicating with lines supplying chambers of the air
mattress and an outlet port in the base wall communicating with the
blower intake port, the gate member having a first end wall a
second end wall, and a horizontal wall connecting the first end
wall and the second end wall that divides the gate member into a
first portion and a second portion, the gate member further having
a first port in the second end wall communicating the first portion
with the outside environment, a second port in the first end wall
communicating with the first portion, and a third port in the first
end wall communicating with the second portion, the gate member
rotatably received by the housing so that the gate member first end
wall is closely proximate to the housing base wall, the gate member
rotatable between a first position aligning the gate member second
port with the housing outlet port, blocking the gate member third
port with the housing base wall and communicating the gate member
second portion with both the valve housing inlet port and the air
mattress supply ports, thereby communicating the blower intake with
the outside environment and communicating the blower exhaust with
the air mattress supply ports, and a second position aligning the
gate member third port with the housing outlet port as the gate
member, blocking the gate member second port with the housing base
wall, communicating the gate member first portion with the valve
housing inlet port and communicating the gate member second portion
with the air mattress supply ports, thereby communicating the
blower exhaust with the outside environment and communicating the
blower intake with the air mattress supply ports to quickly deflate
the air mattress.
8. The system of claim 7, wherein the air mattress supply lines
have electrically controlled valves for controlling the amount of
air that can flow therethrough.
9. The system of claim 7, wherein the air mattress supply lines
have electrically controlled valves for controlling the amount of
air that can flow therethrough, and, the air mattress supply lines
have pressure sensors interposed between the valves and the
chambers of the air mattress for sensing the back pressure in the
chambers of the air mattress and wherein, a control unit
operatively connected to the pressure sensors and the electrically
controlled valves receives signals from the pressure sensors and
responds to those signals by opening or closing the valves until
the pressure sensors indicate a pressure within a preselected
pressure range.
10. The system of claim 7, wherein the air mattress supply lines
have electrically controlled valves for controlling the amount of
air that can flow therethrough, the air mattress supply lines have
pressure sensors interposed between the valves and the chambers of
the air mattress for sensing the back pressure in the chambers of
the air mattress, and, a programmable control unit is operatively
connected to the pressure sensors and the valves, the programmable
control unit receiving pressure signals from the pressure sensors
and responding to those pressure signals by (1) determining if the
pressure signal indicates if a pressure is within a selected range
of pressures or above or below a selected range of pressures, (2)
transmitting a signal to incrementally close the valve in a line
having a pressure that is above the selected range of pressures,
(3) transmitting a signal to incrementally open the valve in a line
having a pressure that is below the selected range of
pressures.
11. The system of claim 7, wherein the air mattress supply lines
have stepper motor controlled valves for controlling the amount of
air that can flow therethrough, the air mattress supply lines have
pressure sensors interposed between the valves and the chambers of
the air mattress for sensing the back pressure in the chambers of
the air mattress, and, a programmable control unit is operatively
connected to the blower motor, the pressure sensors and the valves,
the programmable control unit receiving pressure signals from the
pressure sensors and responding to those pressure signals by (1)
determining if the pressure signal indicates if a pressure is
within a selected range of pressures or above or below a selected
range of pressures, (2) transmitting a signal to incrementally
close the valve in a line having a pressure that is above the
selected range of pressures, (3) transmitting a signal to
incrementally open the valve in a line having a pressure that is
below the selected range of pressures, (4) transmitting a signal to
incrementally increase the supply of electrical power to the blower
motor to increase the blower output if a pressure in a line is
below a selected range of pressures and the valve in that line is
completely open.
12. A rotary valve for controlling the flow of air from between a
blower having an intake port and an exhaust port, an outside
environment and the chambers of a patient supporting low air loss
air mattress, comprising; a housing and a gate member, the housing
including an inlet port communicating with the blower exhaust port,
air mattress supply ports communicating with lines supplying
chambers of the air mattress and an outlet port communicating with
the blower intake port, the housing rotatably receiving the gate
member, the gate member divided by a wall into a first portion and
a second portion and further having a first port communicating the
first portion with the outside environment, a second port
communicating with the first portion and a third port communicating
with the second portion, the gate member rotatable between a first
position aligning the gate member second port with the valve
housing outlet port and communicating the gate member second
portion with the valve housing inlet port and the air mattress
supply ports, thereby communicating the blower intake with the
outside environment and communicating the blower exhaust with the
air mattress supply ports, and a second position aligning the gate
member third port with the valve housing outlet port and
communicating the first portion of the gate member with the valve
housing inlet port and communicating the second portion of the gate
member with the air mattress supply ports, thereby communicating
the blower exhaust with the outside environment and communicating
the blower intake with the air mattress supply ports to quickly
deflate the air mattress.
13. The rotary valve of claim 12 wherein, the housing is
cylindrical having a base wall and a cylindrical outer wall, the
outlet port of the ousing is disposed in the base wall and the
inlet port and the air mattress supply ports are disposed in the
cylindrical outer wall.
14. The rotary valve of claim 12 wherein, the housing is
cylindrical having a base wall and a cylindrical outer wall, the
outlet port of the housing is disposed in the base wall and the
inlet port and the air mattress supply ports are disposed in the
cylindrical outer wall, wherein the gate member has a first end
wall, a second end wall, the wall dividing the gate member into the
first portion and the second portion is a horizontal wall
connecting the first end wall and the second end wall, the first
port is disposed in the second end wall in communication with the
first portion, the second port is disposed in the first end wall in
communication with the first portion and the third port is disposed
in the second end wall in communication with the second portion,
and wherein the housing rotatably receives the gate member so that
the gate member first end wall is in close proximity with the
housing base wall.
Description
FIELD OF THE INVENTION
This invention relates to a control system for controlling the flow
of air to and from the chambers of a low air loss, patient
supporting air mattress.
BACKGROUND OF THE INVENTION
Numerous systems have been proposed for controlling the flow of air
to a low air loss inflatable air mattress. For example, Suzuki et
al., in U.S. Pat. No. 6,108,843 employed a set of on/off valves in
combination with pressure sensors to control pressures within a set
of air sacks of an air mattress. Schild, in U.S. Pat. No. 5,117,518
discloses a rotating valve to alternately supply air to sets of air
chambers in an air mattress. Thomas et, al, in U.S. Pat. No.
5,095,568 teach a flat plate valve system for distributing air to
an air mattress.
The prior art evidences a search for a simple, reliable and compact
means for providing a flow of air to the chambers of a low air loss
air mattress. Numerous complex valves for controlling the flow of
air have been developed.
One object of the present invention is to provide a simple, compact
air mattress air supply and control system that is able to operate
in different modes to supply air to different types of air
mattresses.
Another object of the present invention is to provide an air
mattress air supply and control system having a fan and motor that
will not over heat as is now the case with many existing
systems.
Yet another object of the present invention is to provide an air
mattress air supply and control system that can receive an input
corresponding to the weight of the supported patient, sense
pressure in the chambers of various zones of the mattress, convert
those sensed pressures to interface pressures between the patient
and the mattress depending on the location of the zone and weight
of the patent and then control the flow of air to an air mattress
so that the patient/mattress interface pressure in each zone
remains below a selected value to prevent the formation of bed
sores. Still yet another object of the present invention is to
provide an air mattress
air supply and control system that can be quickly deflated with
reverse air flow so that cardiopulmonary resuscitation can be
administered to a patient supported by the mattress.
SUMMARY OF THE INVENTION
The system of the present invention is a system for supplying air
and controlling the flow of air into and out of the chambers of a
patient supporting air mattress. It includes an electric motor
powered variable speed blower, a two position rotary valve, air
mattress supply lines communicating between the rotary valve and
the chambers of the air mattress, a continuous exhaust line also
connected to the rotary valve, stepper motor controlled valves in
the air mattress supply lines, pressure sensors between the stepper
motor controlled valves and the chambers of the air mattress and a
control unit.
The variable speed blower has an intake and an exhaust port. The
inlet port of the two position rotary valve is connected to the
blower exhaust port. The two position rotary valve can either
direct the flow of air from the blower to the chambers of the air
mattress in a pressurizing mode or route the flow of air from the
air mattress into the intake of the blower in a vacuum mode in
which the air mattress is rapidly deflated. When in the
pressurizing mode, air exits the rotary valve through air mattress
supply ports connected to the air mattres supply lines that supply
air to various chambers of the air mattress. When in the
pressurizing mode, a portion of the air supplied by the blower also
flows out of the rotary valve through the continuous exhaust line.
The continuous exhaust line provides a passageway for air to
continuously flow through the blower to cool the blower. The
stepper motor controlled valves in the air mattress supply lines
can incrementally close to control the flow of air in the air
mattress supply lines. The air pressure sensors which are located
between the stepper motor controlled valves and the chambers of the
air mattress sense the air pressure in the lines leading to the air
mattress. The control unit receives signals from the air pressure
sensors and responds to those signals by controlling the operations
of the blower and the stepper motor controlled valves in such a way
that the air pressure within the air mattress chambers is held
within a selected pressure range.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention and its many attendant objects and advantages will
become better understood upon reading the following description of
the preferred embodiment in conjunction with the following
drawings, wherein:
FIG. 1 is a schematic of the system of the present invention.
FIG. 2 is a perspective view of the rotary valve of the system of
the present invention.
FIG. 3 is a bottom view of the rotary valve of the system of the
present invention taken from plane 3--3 of FIG. 2.
DETAILED DESCRIPTION OF THE INVENTION
The system of the present invention 10 is shown in schematic form
in FIG. 1. System 10 includes an electric motor powered blower 15,
an intake filter 30, a two position rotary valve 100, air mattress
supply lines 302A, 302B, 302C, 302D and 302S for supplying air to
an air mattress 400, continues exhaust line 304, stepper motor
controlled valves 310A, 310B, 310C, and 310D, pressure sensors
312A, 312B, 312C, and 312D, a control unit 50 and a control panel
70.
Variable speed blower 15 is powered by an electric motor (not
shown) such as a 110V AC electric motor. Control unit 50 can
control the power supplied to the blower motor. Blower 15 is a
blower that is not a positive displacement air pump but rather a
centrifugal fan type blower. This type of blower is appropriate in
a system which supplies air to a low air loss air mattress such as
air mattress 400. Air mattress 400 has a large number of small
holes in its upper surfaces to permit air to constantly circulate
around a supported patient.
Blower 15 has an intake port 17 and an exhaust port 19. Rotary
valve 100 is shown schematically in FIG. 1 and is shown in greater
detail in FIG. 2 and FIG. 3. As is shown in FIG. 1, rotary valve
100 has an inlet port 110 that is in pneumatic communication with
exhaust port 19 of blower 15. The blower intake port 17 is
connected by an air tight chamber (not shown) to an outlet port 130
in rotary valve 100. As can be seen schematically in FIG. 1, rotary
valve 100 includes a gate member 200, which in FIG. 1, is shown in
a first position for directing air flow in a pressurizing mode.
Rotary valve 100 has a set of mattress supply ports 112S, 112A,
112B, 112C and 112D as well as a continues exhaust port 114.
Continuos exhaust port 114 connects to a line 304 leading to the
outside environment and provides a passageway for air to constantly
flow through and cool blower 15. Supply port 112S connects to a
line 302S that might be used to inflate a chamber or set of
chambers of the air mattress that might remain inflated at a
relatively constant pressure. A set of air mattress supply lines
302A, 302B, 302C and 302D connect to mattress supply ports 112A,
112B, 112C and 112D respectively and are each interrupted by
control valves 310A, 310B, 310C and 310D and pressure sensors 312A,
312B, 312C and 312D respectively. Although, in the embodiment
shown, air mattress supply lines 302A, 302B, 302C and 302D each
have a control valve and a sensor, it is possible to configure a
system where only some of those supply lines include a control
valve and a sensor.
Each of these identical control valve, sensor arrangements can be
better understood by considering the control valve, sensor
arrangement of air mattress supply line 302A which leads to a
chamber or set of chambers in air mattress 400. Pressure sensor
312A, is used to sense the air pressure in line 302A. Control valve
310A controls the flow of air in line 302A between rotary valve 100
and air mattress 400. Control valve 310A includes a stepper motor
that incrementally opens and closes valve 310A. Both pressure
sensor 312A and control valve 310A are operatively connected to
control unit 50 via lines 54A and 52A respectively.
Preferably, control unit 50 is a programmable control unit that can
receive inputs from a control panel 70. Contorl unit 50 is
connected to pressure sensors 312A, 312B, 312C and 312D via sensor
lines 54A, 54B, 54C and 54D respectively and to control valves
310A, 310B, 310C and 310D via control lines 52A, 52B, 52C and 52D
respectively. Preferably, control unit 50 is also be operatively
connected to the motor that powers blower 15 via a control line 53.
Control unit 50 receives signals from pressure sensors 312A, 312B,
312C and 312D and responds to those signals by sending control
signals to the stepper motors of control valves 310A, 310B, 310C
and 310D and also, if necessary, by adjusting the amount of power
supplied to the motor that powers blower 15.
The operation on one pressure sensor, control valve combination can
be considered in order to understand the operation of all four
pressure sensor, control valve arrangements. Control unit 50
receives a signal from pressure sensor 312A indicating the air
pressure within the set of chambers of air mattress 400 that are
supplied by line 302A. Control unit 50 responds to the pressure
signal to determine if the pressure is within a selected range of
pressures or above or below a selected range of pressures. Control
unit 50 responds to the pressure signal by (1) transmitting a
signal to incrementally close valve 310A when pressure sensor 312A
indicates a pressure that is above the selected range of pressures
or by (2) transmitting a signal to incrementally open valve 310A
when pressure sensor 312A indicates a pressure that is below the
selected range of pressures or by (3) transmitting a signal to the
motor of blower 15 incrementally increase the supply of electrical
power to the blower motor to increase the blower output if pressure
sensor 312A indicates a pressure that is below the selected range
of pressures and valve 310A is completely open.
System 10 may be connected to a type of mattress having transverse
air chambers arranged in zones much like the arrangement shown in
FIG. 1 and can be adapted to control the patient, mattress
interface pressure to prevent the formation of bed sores. Control
unit 50 could include an algorithm for converting sensed pressure
to mattress, patient interface pressure. The mattress, patient
interface pressure is the pressure of contact between the mattress
surface and the body of the patient. If that pressure is too high,
blood circulation under the patient's skin is restricted and the
patient develops bed sores. Such an algorithm would require an
input relating to the weight of the patient and would convert the
measured back pressure from various zones of the mattress to an
approximate mattress, patient interface pressures. Control unit 50
would then receive pressure values from pressure sensors 312A,
312B, 312C and 312D and respond by either opening or closing valves
310A, 310B, 310C and 310D to maintain pressure in the corresponding
chambers of mattress 400 to pressures that correspond to patient,
mattress interface pressures that are just below the acceptable
value. In this way control unit 50 can be adapted within the
invention system to control pressure in a mattress to prevent bed
sores.
The selected pressure range targeted by control unit 50 can be a
constant set of values or a set of values that change with time
depending on a pre-programmed mode that might be selected using
control panel 70. For example, air mattress 400 might be configured
differently from what is shown in FIG. 1, so that the set of
chambers supplied by line 302A would all be on one lateral side of
the air mattress. Control panel 70 might further have a mode
selection option for a patient turning mode whereby chambers on
alternate lateral sides of the air mattress are alternately
inflated and deflated in unison in a cyclic fashion. In this case,
the targeted pressure ranges would be constantly changing as sets
of air chambers are inflated and deflated.
System 10 may also be connected to another type of mattress having
transverse air chambers arranged in a transverse, alternating
manner. A pulsating air mattress could be arranged where such
alternating, staggered sets of chambers would be inflated and
deflated in accordance with a programmed set of instructions.
Accordingly, system 10 is highly versatile and can be used to
supply air to various types of air mattresses such as a rotational
therapy mattress, a pulsating mattress or constant pressure
mattress.
System 10 is also capable of supporting a cardiopulmonary
resuscitation (CPR) mode wherein an air mattress connected to the
system can be quickly deflated so that the patient may be lowered
to a firm surface for CPR. The CPR mode is activated by turning
gate member 200 of rotary valve 100 to a second position shown in
phantom in FIG. 1. When in the second position, gate member 200
directs air from air mattress 400 into intake 17 of blower 15 while
air leaving blower 15 is directed through filter 30 to the outside
environment. Because air from air mattress 400 is now routed to
intake 17 of blower 15, air mattress 400 quickly deflates.
The arrangement of rotary valve 100 is illustrated in detain in
FIG. 2. As can be seen in FIG. 2, rotary valve 100 includes a valve
housing 101 and a gate member 200. Valve housing 101 has an open
cylindrical shape and includes an outer wall 105 and a base wall
102. Outer wall 105 has an inlet port 110 that connects with
exhaust port 19 of blower 15. Outer wall 105 of valve housing 101
also has air mattress supply ports 112S, 112A, 112B, 112C and 112D
for supplying air to various sets of chambers of air mattress 400
shown in FIG. 1 as well as a continuous exhaust port 114. Air
mattress supply ports 112S, 112A, 112B, 112C and 112D and exhaust
port 114 are shown more clearly in FIG. 3 which is a view taken
from plane 3--3 of FIG. 2. Base wall 102 of housing 101 has an
outlet port 130. Outlet port 130 and intake port 110 are centered
upon the same diametric plane of housing 101.
Gate member 200 is received by valve housing 101 so that it can
rotate within valve housing 101. Gate member 200 has a first
circular end wall 210 at one end, a second circular end wall 212 at
the opposite end, a cylindrical wall 216 and a horizontal wall 215
that extends between and connects first end wall 210 and the second
end wall 212. First end wail 210 of gate member 200 comes into
close proximity or contact with base wall 102 of housing 101 when
gate member 200 in inserted into housing 101. Second end wall 212
closes rotary valve 100 when gate member 200 in inserted into
housing 101. Horizontal wall 215 divides gate member 200 into a
first portion which is above horizontal wall 215 in FIG. 2 and a
second portion which is below horizontal wall 215 in FIG. 2. Second
end wall 212 has first ports 220 above horizontal wall 215. First
ports 220 could easily be combined into one port. First ports 220
can be positioned anywhere in second end wall 212 above horizontal
wall 215. First end wall 210 has a second port 230 positioned above
horizontal wall 215 and a third port 232 positioned below
horizontal wall 215. As can be better understood by referring to
FIG. 1, ports 220 lead to filter 30 and the outside environment.
Cylindrical wall 216 of gate member 200 is sized to fit within
housing 101. An upper wall port 217 opens into the upper chamber of
gate member 200 while a very extensive lower wall port 218 opens up
almost all of the lower chamber of gate member 200. Although upper
wall port 217 is shown in FIG. 2 as an opening in a substantially
complete cylindrical wall 216, gate member 200 can still function
even if upper wall port 217 is as extensive as lower wall port 218.
With such an open configuration, gate member 200 presents first and
second portions that are mostly bounded by the first and second end
walls of gate member 200, horizontal wall 215 and cylindrical outer
wall 105 of housing 101 when gate member 200 is inserted into
housing 101.
The various ports and openings of valve housing 101 and gate member
200 are arranged so that the valve can operate in a first position
in which pressurized air is delivered to the air mattress a second
position in which air is pulled from the air mattress to quickly
deflate the air mattress. Air mattress supply ports 112S, 112A,
112B, 112C and 112D and exhaust port 114 are positioned in a
pattern that is adjacent to inlet port 110 so that when gate member
200 is tilted in the first position, air mattress supply ports
112S, 112A, 112B, 112C and 112D, exhaust port 114 and inlet port
110 are on one side of horizontal wall 215 of gate member 200 in
communication with the second portion of the gate member.
When gate member 200 is in the first position, air can flow through
inlet port 110 of housing 101, into the second portion of gate
member 200 and then out through air mattress supply ports 112S,
112A, 112B, 112C and 112D and exhaust port 114. Also while gate
member 215 is in the first position, second port 230 of gate member
200 is aligned with outlet port 130 of valve housing 101 (while
third port 232 is blocked by base wall 102 of valve housing 101) so
that outside air can flow through first ports 220 in second end
wall 212, into the first portion of gate member 200, through second
port 230 of gate member 200, through outlet port 130 of housing 101
and into the intake of blower 15. When gate member 200 is in the
first, pressurizing position, air from blower 15 is routed to air
mattress 400 shown in FIG. 1, while outside air is drawn in through
filter 30 shown in FIG. 1 and into the intake of blower 15.
When gate member 200 is turned to a second position, horizontal
wall 215 is interposed between inlet port 110 and air mattress
supply ports 112S, 112A, 112B, 112C and 112D as well as exhaust
port 114. When the gate member 200 is in the second position, third
port 232 of gate member 200 aligns with outlet port 130 of housing
101 so that air is pulled in through air mattress supply ports
112S, 112A, 112B, 112C and 112D, through third port 232, then
through outlet port 130 of housing 101 and into the intake of
blower 15. Also when gate member 200 is in the second, blower
exhaust air passes through inlet port 110 of housing 101 and out
through first ports 220 into the outside environment (while second
port 230 is blocked by base wall 102 of housing 101). When gate
member 200 is in this second position, air is drawn out of air
mattress 400 shown in FIG. 1 and blower exhaust is expelled into
the outside environment through filter 30 shown in FIG. 1 causing
air mattress 400 to quickly deflate. To facilitate the vacuum mode,
it may also be advantageous to locate exhaust port 114 in an
outside radial position such as in the location of air mattress
supply port 112B shown in FIG. 3 and then to add a tab 240 to gate
member 200 that only obstructs the relocated exhaust port 114 when
gate member 200 is in the second position. This would stop air back
flow through exhaust line 304 when the gate member is in the
second, vacuum position. In the alternative, it may be advantageous
to place a one way flapper valve in line exhaust line 304 to
prevent such back flow when the system is operating in the rapid
deflating vacuum mode.
Preferably, rotary valve 100 can be fashioned from injected molded
plastic. It is preferable to mount gate member 200 in a spring
biased manner so that gate member is pushed into housing 101 to
make firm contact. Because gate member 200 is intended to be
operated manually, it may also be advantageous to mount gate member
200 within housing 101 so that it can only move between the first
and second positions. Moreover, it would be preferable to have
corresponding protrusions and recesses in first end wall 210 of
gate member 200 and base wall 101 of housing 101 respectively that
engage each other when gate member 200 is in a first or a second
position to provide an operator with tactile feed-back to indicate
that rotary valve 100 is either in the first or the second position
but not between the first or the second position.
Obviously, in view of the preferred embodiments described above,
numerous modifications and variations of the preferred embodiments
disclosed herein are possible and will occur to those skilled in
the art in view of this description. For example, many functions
and advantages are described for the preferred embodiments, but in
some uses of the invention, not all of these functions and
advantages would be needed. Therefore, I contemplate the use of the
invention using fewer than the complete set of noted functions and
advantages. Moreover, several species and embodiments of the
invention are disclosed herein, but not all are specifically
claimed, although all are covered by generic claims. Nevertheless,
it is my intention that each and every one of these species and
embodiments, and the equivalents thereof, be encompassed and
protected within the scope of the following claims, and no
dedication to the public is intended by virtue of the lack of
claims specific to any individual species. Accordingly, it is
expressly to be understood that these modifications and variations,
and the equivalents thereof, are to be considered within the spirit
and scope of the invention as defined by the following claims,
wherein,
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